Fluid control system



June 11, 1940. BARRETT FLUID CONTROL SYSTEM Filed Aug. 24, 1935 6 Sheets-Sheet l M R Va m T M June 11, 1940. R T 2,203,939

FLUID CONTROL SYSTEM Filed Aug. 24, 1936 6 Sheets-Sheet 2 INVENTOR f 7?, 347729225 BY w fifrok zva s.

June 11, 1940. E T 2,203,939 Q FLUID CONTROL SYSTEM Filed Aug. 24, 1936 6 Sheets-Sheet 3 "/a/ O 6/ Iifiinm 88 8 Q 5mm 6 ml: 0 o o o 0 lNVEN-TOR [/0 Z'd'warz? R Barr-e22 June 1940- E. R. BARRETT v FLUID CONTROL SYSTEM Filed Aug.

6 Sheets-Sheet 4 ATTORNEYS.

June 11, BARRETT 2,203,939

FLUID CONTROL SYSTEM Fi1ed A ug. 24; 1936 6 Sheets-Sheet 5 I INVENTOR. Edward 7?. B47733.

E45- BY ATTORNEYS.

June 11, .1940. E. R. BARRETT FLUID CONTROL SYSTEM Filed Aug. 24, 1936 6 Sheets-Sheet 6 WM WN\ 0 fua' M.

ATTORNEYS.

Patented June 11,

FLUID CONTROL SYSTEM Edward R. Barrett, Detroit, Mich., 'assignor to Gar Wood Industries, Inc., a corporation of' Michigan Application August 24, 1936, Serial No. 97,490 3 Claims." (01.121-465) This invention relates to fluid distribution systems. More particularly it relates to a novel and improved type of fluid distribution particularly adapted to be associated witha motive power a 5 unit for selectively controlling a plurality of, re-

motely disposed hydraulic cylinders. While it will be clearly apparent from the fol lowing description that the apparatus disclosed in the present invention will find wide and prac- 1 tical utility in many and different installations, the specific embodiment of the invention illustrated herein showsthe apparatus as applied to a specific form of road'working machine. It will be apparent that the novel and improved valve structure disclosed will be equally well applicable in any installation where it is desired to control selectively a plurality of relatively remotely disposed hydraulic actuating cylinders. "Ihe apparatus will in general flnd great utility in many p and various fluid distribution systems. The present invention contemplates the provision of a motive power unit including a power take-off mechanism, which serves to drive a fluid pump. Fluid under pressure delivered by the ,pump is fed to a bank of independently actuatable control valves which serve to distribute the fluid selectively to any one of a plurality of hydraulic actuating cylinders, which may be located a substantial dis'tanceirom the distributor a valve mechanism and may be connected thereto by means of suitable flexible conduits. A It is an object of the present invention to provide a valve construction comprising a plurality of control valves arranged in side by side relation and interconnected by means of a suitable manifold construction, whereby fluid pressure from a single source may selectively be utilized for oper ating any of the hydraulic cylinders to which the valves are connected entirely independent of other hydraulic cylinders.

tion to provide a-valve .construction of this general type in which each of the valves includes a pair of plungers serving to control the distribution oi fluid from the pump into the system in a direction and manner such as may be desired and to provide in combination with such valve plungers poppet valves which serve to automatically seal the systemagainst leakage when a surface over which it travels.

It is a still further object of the present inven ing a plurality of relatively movable parts actuated by a hydraulic cylinder mechanism. The tractor or other motive power unit serves to provide means for causing movement of the road working machine over the surface of the ground and a suitable power take-off mechanism asso- ,ciated with the tractor motor serves to pump a constant supply of fluid under pressure for the purpose of actuating the hydraulic cylinders serving to control actuation of. the road working machine. The improved distributor valve of the present invention serves to provide means by which the actuating cylinders may be conveniently selectively controlled. 1

The present invention also contemplates the provision of a road working machine comprising a framework having front and rear sections pivotally connected together and hydraulic means associated with such pivotal connections for controlling pivotal movement of said sections with respect to each other. in order to adjust the vertical position of the apparatus as a whole to the A scoop or bowl is pivotally mounted upon one of the sections and hydraulic means are provided for effecting a tilting movement of this scoop bowl with respect to the framein which it is mounted and the bowl includes a pivotally mounted, independently actuated gate for closing the front of the bowl, in order that, after a predetermined amount of material has been scooped up by the bowl, such material may be retained in position for convenient transportation.

It is a general object of the present invention to provide an assembly of apparatus, such as has been described above, which will be simple in construction, convenient and positivein' operation, and of. such form that the apparatus as a whole may be easily and conveniently attached to tractors or other sources of motive power without necessary modifications of conventional constructions.

A still further object of the present invention consists in the provision of a fluid distribution valve .assembly in which a plurality ofvalves are arranged in co-operative position side by side.

suitable distributing manifold which -serves to provide means for simultaneously feeding fluid under pressure to the inlet port portions of. all of the valves in the bank. The manifold includes an inlet and an outlet port for each of the valves so that fluid supplied to the valve maybe distributed to the hydraulic actuating cylinder with which the valve is associated and the other port The valves are preferably inter-connected by a of the valve provides a duct whereby fluid may be conveniently bled from the one side of the hydraulic cylinder as fluid is supplied to the opposite side thereof. The valves arranged in the bank are further inter-connected by means of a manifold which serves to feed fluid bled from the first valve in the bank through the remaining valves in the bank before this fluid is permitted to return to the supply reservoir.

The invention further contemplates the provision of a novel form of road machine construction in which the road working machine as a whole is constructed of a pair of sections pivotally connected together in such a manner that pivotal movement of one of the sections with respect to the other serves to raise and lower the position of the road working apparatus with respect to the surface over which the machine travels.- Hydraulic means are provided for the purpose of regulating the angular position of the component parts of the machines in order that the relative angular pivotal position of these considered in connection with the accompanying drawings forming a part thereof.

50 the valve housing, showing one of the distribu- In the drawings:

Figure 1 is a fragmentary, side elevational. view of the improved road working machine, illus, trating the same coupled to the rear end of a conventional caterpillar type tractor motive power unit;

Fig. 2 is a plan view of the road working ma-.

Fig. 3-is a perspective view. of the fluid pump,

reservoir and distributor valve assembly, which is adapted to be secured to the rear of the motive power unit;

Fig. 4 is a vertical sectional view taken substantially on the line 4-4 of Fig. 3, illustrating the interior construction of the upper portion of tor valves in side elevation;

Fig. ,5 is a rear'elevational view of the upper portion of the valve housing, illustrating in detail the manifold for supplying fluid to, and distributing fluid from the distributor valve assembly;

Fig. 6 is a transverse sectional view taken sub stantially on the line 66 of Fig. 5, illustrating in detail the interior construction of a portion of the manifold and the duct for supplying fluid thereto;

Fig. '7 is a transverse sectional view taken substantially on the line of Fig. 5, illustrating in detail the interior construction of the distributing manifold, and showing a pair of fluid distribution ports;

. Fig. 8 is a sectional view taken substantially on the line 8-8 of Fig. 5, illustrating in detail one of the fluid distribution ports and the manner in which the manifold is-secured to the housing;

Fig. 9 is a transverse sectional view taken substantially on the line 99 of Fig. 5, illustrating in detail the release mechanism for excessive pressures in the distributing manifold;

Fig. 10 is a transverse sectional view taken subtor or other source of motive power I3.

interior construction of a portion of the bleed manifold shown therein;

Fig. 13 is 'a transverse sectional view taken Q substantially on the line I3--l3 of Fig. 11, illus-.

trating in further detail the interior construc: tion of the bleed manifold shown therein; Fig. 14 is a transverse sectional view taken substantially on the line "-44 of, Fig. 11, still g.

further illustrating the interior construction of the bleed manifold;

Fig- 15 is a sectional view taken substantially on the line l5l5' of Fig. 10, illustrating in detail the under surface of one of the valves making up the distributor valve unit; and

Fig. 16 is a transverse,'sectional view taken through the valve bank substantially on the line l6-l6 of Fig. 11, illustrating in detail the internal construction and arrangement of ports of the various valves and the manner in which the.

valves are inter-connected for communication by means of the base manifold.

With more particular reference to the drawing a part of the present invention, is clearly illustrated in Figs. 1 and 2. 'It will be readily? appreciated that the particular specific form of road machine illustrated in Figs. 1 and 2 of the drawings is merely illustrative of one of a great number of different types of apparatus which may be conveniently and successfully operated by 5 ings, it'will be seen that the road machine, formthe improved fluid distribution system described below.

The particular apparatus shown, is in the nature of a travelling scoop and includes a forward frame section Hi to which is-secured a pivotally mounted eye H for securing the framework to a suitable forked fitting l2 on the rear of a trac- The eye II, and the forked fitting I! may be detachably coupled together by a displaceablecoupling pin It, which will provide easy and convenient mean for uncoupling the apparatus at will.

The carriage frame it) has journalled thereon a pair of road wheels I6 which may, as shown,'

bemounted upon suitable stub axles for free rotation. Pivotally mounted on the framework l0, preferably substantially co-axially with the wheels I6, is an upwardly extending frame II. The frame IT, at its upper end, isprovided with a pair of spaced rearwardly extending projections I8,

' which provide means for pivotally interconnecting' a rear frame. The rear frame comprises a pair of longitudinally extending side frame members l9, which are transversely interconnected at'their forward ends by means of a brace member 20. The brace member 20 hasa pair of prowardly and upwardly projecting therefrom, a I

relatively strong arm 23. A cylinder is pivotally connected at its lower end to the lower portion of the frame I1 and has a piston cooperating therewith, the rod 26 of such piston being pivotally connected to the outer end of the arm 23. The cylinder is preferably closed at both ends and has a pair of conduits 21 and 28 providing communication with the respective lower and upper ends of the cylinder.

From the foregoing, it will-beappreciatedthat as fluid under pressure is supplied to the cylinder through either of the conduits 21 or 28, such fluid will effect a movement of the piston within the cylinder and consequently cause a vertical movement of the piston rod26. Due to the pivotal connection of the piston rod 26 with the projecting arm 23, which, as has been explained above, is rigid with the rear frame I9, such movement of the piston rod will inherently cause a pivotal movement of the frame work llwith respect to the frame H, which movement will serve to raise and lower the position of the frame I!) as may be desired, The function and operation of this apparatus will be described in greater detail below. i

The side frame members H are inter-connected adjacent their rear ends by means of a transversely extending brace bar 30 and the extreme ends of these frame members are each provided with stub axles upon which are journalled suitable pairs of road wheels 3|, which serve to support the rear end of the framework is upon the surfaceover which it is adapted to travel. It will be clearly appreciated that vertical movement of the piston rod 26 will cause a substantial variance in the distance between the wheels l6 and the wheels 3|, and a general elongation orshortening of the road machine as a whole, as well as an adjustment of the vertical position of the frame I9.

A scoop bowl is pivotally supported in suitable brackets 36 on the side frame I9, as clearly .seen in Fig; 1. The scoop bowl 35. is preferably provided with a downwardly sloped forward edge 360 and a bottom wall which normally lies substantially horizontal to the surface over which the road machine travels. It will benoted that the point of pivotal securement of the scoop bowl 35 is well forward of the general body thereof and it will be appreciated that this construction tends to prevent the scoop from moving about its pivot when the forward edge 360 thereof engages the ground or engages a body of material to be moved. A pair of cylinders are mounted in suitable brackets 4| permanently secured to 55 the side frame members l9, one of the cylinders being located on each side of the framework. The cylinderslll each contain a piston, which piston has a piston rod connected thereto extending outwardly of the cylinder and pivotally secured at the point 43 toasuitable'portion of the framework of. the scoop bowl 35 above the pivotal mounting thereof in the bracket 35.. It will be appreciated, therefore, that as fluid is supplied to the cylinders 40 to effect an outward movement of the pistons therein, the piston rods will effect a pivotal movement of the scoop bowl about its pivotal axis and consequently will serve to provide efiectivemeans for dumping the scoop bowl when such is desired. It will be appreciated at this point that the pivotal mounting of the scoop bowl substantially at the forward portion through flexible conduits46'and 41, the conduit 46 communicating with the forward end of each of the cylinders and the conduit 41 communicat ing with the rear-end of each of the cylinders. These flexible conduits 46 and 41 are each connected to suitable permanent or rigid conduits 48 and 49, respectively, which extend forwardly along the side frame members and to a point adjacent the front end of the road machine. Each of these conduits is provided. with a suitable fitting at its forward end adapted to form convenient means for connecting flexible hoses, hereinafter described in detail. 5

From the foregoing it will be appreciated that, as fluid under pressure is supplied through the conduit 49, this fluid will simultaneously'be discharged .into the lower ends of the cylinders 40 located at each of the sides of the scoop bowl and will cause an outward movement of the pistons within the cylinders. and a consequent tilting of the scoop bowl about its pivotal mounting 36. It will be appreciated that the forward movement of the pistons within the cylinders 40 will serve to expel fluid from the interior of the cylinders out through the flexible conduits 46 and out through the conduit 48, returning the same to the valve mechanism. Itwill be seen that the selective supply of fluid to either end of the cylinders 40 such as may be desired serves to provide hydraulic means for accurately regulating the angular position of thescoop bowl with respect to the framework in which it is mounted and, as has been described above, the vertical position of the'framework in which the scoop bowl is mounted may be conveniently regulated marginal edge adapted to cooperate with the forward marginal edge of the scoop bowl 35. The gate 50 as a whole is pivoted in the side frame members at the points 5l and it will be seen that, as the gate 50 is arcuately moved about its pivot, it will serve to either close or expose the entire front of the scoop bowl 35. A pair of cylinders 53 are mounted on each of, the side frame members I! and these cylinders each serve to house a piston and connected piston rod 54, the outer 'end of which piston -rod is pivotally connected to the gate 50 at the point 55. Each of the cylinders 53 is preferably pivotally mounted at the point 56 on the side frame members l9 so that, as pivotal movement of the gate 50 about its pivot 5| takes place, the cylinder 53 will be permitted to pivot about its own pivotal mounting. Fluid is supplied to the rear end of each of the cylinders 53 by means of conduits 58, which conduits are connected by means of suitable flexible connections 59 to a rigid pipe 60, extend ing forwardly and provided at its forward end with a fitting for the connection of a suitable flexible hose hereinafter described in detail. The forward end of each of the cylinders 53 is likewise provided with a fluid connection 62 which serves to provide communication between the forward end of each of the cylinders and a rigid conduit 63 having its forward end disposed adjacent the forward end of the conduit 6ll.

From the foregoing it will be apparent that as fluid under pressure is supplied through the conscoop bowl and for providing pivotal movement effecting an opening or closure of the gate associated with the scoop bowl, and that further, all of the hydraulic means for accomplishing the above purposes are independent of' each other and conveniently adapted for separate actuation.

Novel and improved means are provided for selectively supplying fluid to each of the hydraulic actuating cylinders described above in order that an operator may conveniently control the vertical position of the scoop, the dumping of the scoop or the actuation of the gate, and the fluid distribution system hereinafter described is so constructed and arranged that this control may be mounted in a position remote from the road scraper machine and convenient to the driver or operator of the motive power unit which serves to cause movement of the scoop.

In order to accomplish the selective distribu tion of fluid to the various hydraulic actuating cylinders, three control valves 10, II and I2 are disposed side by side and, as will hereinafter be more clearly seen, the first of these valves I0 serves to control the supply of fluid to and the bleeding of fluid from the cylinder 25 which, as has been described above, serves to regulate the vertical position of the scoop. The valve II serves to control the supply of fluid to and the bleeding of the fluid from the pair of cylinders 40 which serve. to dump the scoop, and the valve I2 serves to control the supply of fluid to effect the control of the pivotally mounted gate 50.

The valves 10, II and 12 are of the type'shown.

and described in detail in applicants co-pendp ing application, Serial No. 97,489, filed August 24,

1936, and assigned to the assignee of the present invention. Reference may be had to this copending application in order to obtain a more complete understanding of the specific advantageous features of each of the valves and the particular adaptability thereof to fluid control systems of the general type disclosed in the present application. In the rear face each of the valves is provided with arl inlet port I5 and upper and lower fluid feed ports I8 and 11, re-

spectively. These three ports of each valve are" covered and enclosed. by a manifold 18 common to all of the valves in the bank. The manifold is clearly seen in Figs. 3 to 9, inclusive. .It is noted that this manifold includes a pair of ports and 8I which respectively communicate with the ports I6 and 11 of the valve I0. Likewise, the manifold is provided with a pair of ports 82 and 83 which communicate respectively with the.

ports 16 and "1 of the valve II and a pair of ports. and 85 which respectively communicate with the ports I8 and M of the valve I2. The manifold is provided with a hollow interior port 86 which communicates with all three of the inlet or feed ports 15 of the valves 10, II and I2.

This feed port 86 communicates through a duct 81 with a fluid supply fitting 88 through which fluid may be supplied to the interior of the mania fold I8 and, consequently, simultaneously made available at all of the inlet ports I5.

It has been found desirable to provide a pressure relief valve 89 which is urged against. its seat by means of a spring 80 and serves to control the flow of fluid under pressure through a port 9| in the end of the feed duct 86. The force by which the valve member 89 is urged against its seat may conveniently be controlled by an adjustable set screw 92 threaded througha suitable plug 98 in the end of the manifold I8. In practice, this screw is preferably ad justed to a position such that the pressure exerted -ed directly to the valve members I0, 'II' and 12,

it has been found preferable to mount the valve members in an enclosing housing I00. The rear wall of the upper portion of the housing I00 is closed by means of a sheet metal plate IOI securely bolted in position on the rear wall of the housing by means of a series of bolts I02. This plate I0-I is provided with a plurality of apertures adapted to register with the ports 15, 18 and 11 of each of the valves and is provided adjacent each of these ports with a pair of holes adapted to receive bolts I03 passed through the manifold, through the plate and threadably received by the valve housings 10, 'II and I2, re- I spectively. A suitable sheet of packing or gasket material may be disposed between the manifold and surface of the plate IM .to prevent leakage of fluid from the ports at this point, if desired. It will be seen that the mounting of the manifold I8 and valves 10, II and I2 on the plate IOI serves to provide a convenient means of permanently supporting each of the valves within the housing I00. The housing I00 is formed in its vertical central portion to provide a. reservoir I 05 for maintaining a surplus supply of working fluid, such as oil, which may be conveniently supplied to the valves, by the mechanism-hereinafter described, and it will be seen that a partition member I08, which serves to separate the reservoir I05 from the upperinterior 'portion of the housing I00 in which the valves are housed, is provided with a plurality of apertures I01 which serve to permit the return of fluid bled from the valves to the reservoir I05. .The plate IOI may be, provided with an aperture adapted to reach within a port I08 communicating with the-escape valve 89 so' that any fluid escaping through this valv e will inherently be returned to the reservoir I05. in many respects identical in construction and the will beseen that fluid is supplied to the ink of valves through the port 81 by means of a pipe The three valves I0, II and I2 are IIO which extends downwardly and is connected to the outlet of a gear'pump III located in the lower portion of the housing I00 beneath the reservoir I05. The gear pump III is of conven tion'al construction and the apparatus of the present invention may utilize any fluid pump' off IIZof the tractor or motive power unit with i clear byreference to Fig. 1 of the drawings that H the housing I is adapted to be mounted at. the

- ber I 26 described above.

rear central portion of a tractor or other motive power unit H5 and in the apparatus disclosed herein, it has been found particularly satisfactory to utilize a type of motive power unit in which the Power take-off mechanism is located in the rear central portion in order that the housing I00 may be mounted in the rear central portion convenient to the driver's seat and power take-off mechanism.

It will be readily appreciated that the unit housing I00 may "be located in substantially any position that is desired as long as it is conven ienitly available to the driver of the motive power no t.

The inlet side of the pump is connected by means ofa suitable conduit with the lower side of the reservoir I05 in order that this pump may take fluid from the reservoir I05 and deliver such fluid under pressure through the conduit IIO to themanifold 18. It will be seen that this fluid under pressure is delivered through the port 61 into the transversely extending duct 86 which, as. has been described above, communicates with the inlet 15 of each of the valve units H and 12.

The valve member 10 includes a cast housing having a rather complex internal construction of ports and passageways, which is described in detail in applicant's prior co-pending application referred to above. Inasmuch as the specific construction of the valves per se forms no part of the present invention, the details of structure thereof will be dealt with herein only in so far as they have bearing on the general system forming the basis of the present invention.

It will be clear that the ports open into a chamber I which surrounds and provides a port communicating with a cylindrical bore I2I extending through the housing of the valve. A valve plunger I22 is provided which closely fits this hollow cylindrical bore I2I and is provided with reduced diameter portions I23, I24 and I25. Chambers I26 and I21 form annular ports communicating with the bore I2I in spaced relation above and below the annular port I20. It will be seen that the reduced diameter portions I23 and I24 are sufficiently long so that in one position of the plunger, these reduced diameter portions serve to establish communication with the adjacent vertically spaced ports. The ports I26 and I21 communicate with a central chamber I26 which serves to conduct fluid through the distributing valve mechanism hereinafter described in detail. The port 16 comunicats with 'a chamber I30 and the port 11 communicateswith a chamber I3I. Communication with these chamhers is controlled by means of poppet valves I32 and I33, respectively, which-poppet valves have a common stem I34. The axial central portion of this stem I34 is enlarged to provide a pistonlike member I35 which is adapted to cooperate with a cylindrical bore formed in the central portion of the housing. The lower portion of the cylindri cal bore in which the pistonlike member I35 operates is in communication with the central cham- An annular fluid distribution chamber I36has a port whichcommunb cates with. the bore in which the pistonlike member operates and it is seen that the upp r end of the bore in which this pistonlike member operates opens into a chamber I31 which is in communication with the ports controlled by the lm pet valve I32. A chamber I39 is likewise in communication with the ports controlled by the poppet valve I33 and it is seen that the chambers I36, I31 and I39 each communicate through annularports I40, MI and I42, respectively, which Ports establish communication with a cylindrical bore I43 controlled bya plunger valve I44. The plunger valve I44 has a pair of enlarged diameter portions I45 and I46, respectively, which enlarged diameter portions serve to fit closely within the I bore I43 and control communication between the ports I, I42, and I40. As is clear by reference to Fig. 10 of the drawings, the plungers I22 and I44 are rigidly interconnected by means of a cross-bar I48 in order that the two plungers will at all times be simultaneously actuated.

A vertically disposed operating rod I 50 extends upwardly through an upper wall I5I of the housing I00. Thelower end of this operating rod I50 is connected to the central portion of the cross--.

bar I48 interconnecting. the valve plungers I22 and I44. A suitable base casting I52 is. secured by meansof suitable bolts to the upper surface of the cover I5I and this base casting I52serves to provide means for supporting an operating handle I53 which is generally L shaped in configuration in the form of a bell crank arm. The

handle I53. is secured to the base casting I52 by means of a pair of pivotally connected links I54 and one arm of the bell crank is pivotally connected at its ends to the upper end of the vertically disposed'operating arm I50. It will be apparent that movement of the handle I53 will serve to cause vertical movement of the plungers I22 and I44 within their respective bores in the valve housing member 10.

The valve plunger I22 is provided with an in temal counter-bore I which opens, through a plurality of lateral ports I6I, adjacent its upper end and through a second set of lateral ports I62 adjacent its lower end. The lower end of this plunger extends through the lower side of the housing 10 and for a substantial distance downwardly therefrom through a manifold I65 and on through an aperture in the lower side of the manifold. The manifold is provided with two separate chambers into which the openings in the bottom of the valve housing 10 open. The first of these chambers I10 surrounds the plunger I22 at the point where this plunger extends through the manifold. The second of these chambers I1I communicates with an annular pc'rt I12 adjacent the lower end of the bore I2I in which the valve plunger I22 ismounted.

, The operation of the valve is substantially as follows:

' V As fluid under pressure is supplied through the ports 15, it will flow inwardly into the valve housing into the annular port I 20 surrounding the bore I2I. When the valve is in the position shown in Fig. 16. of the drawings, it will be clear that the lateral ports I 6| which communicate with the hollow interior of the valve plunger I22 will register with the ports I20 and consequently the fluid under pressure will flow into this hollow bore. This fluid flows down through the hollow bore I60 of the valve and is permitted to escape tlirough the lateral ports I62 at the lower end thereof into the chamber I10. Due to the reduced diameter portion adjacent the lower end of the valve plunger, this fluid may flow upwardly from the chamber I10 and out through the annular port I12 into the chamber I1I.

The manifold I65 is preferably a single integral casting which is bolted permanently to the lower sides of all three of the valves 10, II and 12. It

will be clear that the chamber I'll in this manifold communicates by means of a passage I18 with a chamber I11 surrounding the lower end of a plunger I18 in the-valve H, which plunger is somewhat similar in construction and function to the plunger I22 described in connection with the valve 18. The plunger I18 is of substantially the same general outer configuration as the plunger I22 and cooperates with a series of ports within a hollow bore in substantially the same manner. The only difference between these two valve plungers is that the counter-bore in the valve plunger I18 is considerably shorter than the counter-bore in the valve I22 and the upper series 'of lateral ports IGI is omitted. The valve plunger I18 is provided with a counter-bore I88 which communicates through a series of lateral ports I8I with the chamber I11. The function of this counter-bore and the lateral ports I8I is merely to balance the pressure on both sides of the valve in order that in all positions the valve will not have any tendency to move axially, and, as will hereinafter be more clearly seen, irrespective of the position in which the valve is adjusted, it will atall times have equal forces balanced on both sides thereof. Consequently, there will be. no"

tendency for axial movement of the valve as a result of fluid pressure imposed thereon.

The fluid entering the chamber I11 may flow upwardly therein past a reduced diameter portion I83 adjacent the lower end of the valve plunger I18 and out through an annular port I12 communicating with the hollow bore in which this valve plunger operates. The annular port I12 is substantially identical in construction with annular port I12 described above and this port communicates through a suitable passageway with a chamber I88 in the manifold I65. The

chamber I86 is substantially identical in con struction withthe chamber "I described above and communicates through a duct I88, seen in dotted lines in Fig. 11 similar in construction to the duct I18, with a chamber I89 surrounding the lower end of the primary plunger I98 of the valve 12. The valve plunger I98 is substantially identical in construction with the valve plunger I18 and it will be seen that fluid may enter the lateral ports at the end thereof to provide a balanced pressure on the end of the valve and at the same valves is'provided with a fluid control plunger I which in the valve structure II is interconnected by means'of across-bar I98 with the plunger I18 and which in the valve 12 is connected by a crossbar I91 with the valve plunger I98. The crossbar I96 has connected thereto an upwardly ex tending operating rod I98 which extends through the upper plate I5I of the housing I88 and is adapted to be actuated by a handle I 99 similar in construction to the handle I53. The cross-bar I91 likewise has connected thereto a vertical operating rod 288, which is adapted to be actuated by a'handle 28I similar in construction to the handles I53 and I99.

As is clearly shown in Fig. 10, the vertically disposed operating rods I58, I88, and 288 may each have a plurality of spaced notches 282 formed in the side thereof at the points where these operating rods extend through their respective base castings I52. A spring pressed ball 283 cooperates with these notches to retain the operating rods in any one of three predetermined adjusted positions. The function of the various valves when in these three positions will become clearly apparent from the following description:

The valve plunger I18 has a reduced diameter portion 2I8 similar in construction and arrangement to reduced diameter portion I23 described above and a second reduced diameter portion 2 identical with the reduced diameter portion I24 on the valve I22. Similarly, the valve plunger I98 has an upper reduced diameter portion 2I2 and a lower reduced diameter portion 2I3 similar in construction and arrangement to'the reduced diameter portions I23 and I24, respectively, formed on the valve plunger I22. Inasmuch as the valve structures H and 12 are identical in construction with the valve 18 in all respects except the primary plungers thereof, similar reference characters have been utilized in general for designating the ports thereof.

When all three valves are in the position shown .in Fig. 10, it will'be apparent that fluid supplied by the pump through the conduit I I8 to the manifold 18 will be available at the three inlet ports 15 of the valves.

valves and ,fill the annular ports I28 surrounding the bores in which the primary plungers of each of the valves is disposed. As has been explained above, the fluid entering the ports 15 of the valve 18 will enter the hollow interior of the plunger I22 through the ports I 8|. However, it will be seen that inasmuch asthe plungers I18 and I98 do not have. the interior bore extending to this point and are not provided with ports similar to the lateral ports I6], the fluid, under pressure will be blocked against further entryinto the housings of the valves H and 12 due to the presence of the plungers I18 and I98 blocking the annular ports I28. 'I'hefluid entering the annular port I28 in the valve 18 will pass downwardly through the hollow interiorof the valve plunger I22 and upwardly past the reduced diameter portion "I of this valve into .the chamber "I along the passageway I18 into the chamber I11 upwardly past the reduced diameter portion I83 of the valve plunger I18 into the ports I12 thereof and downwardly into the chamber I88.

This fluid will then pass along through the duct I88 into the chamber I89 and upwardly past reduced diameter portion I 9| of the valve plunger I98 into the chamber I12 thereof and downwardly through the bleed ports I93, where this fluid may be returned by gravity to the reservoir I85 in the housing I88. It will be appreciated that the pump will maintain this circulation of fluid under pressure and that inasmuch as the fluid has a free passageway through which it may bleed, no actuation of the hydraulic cylinders will be obtained when. the-valves are in this position. It will be appreciated that when the valves are in the position shown, the operation of the apparatus is in neutral and the pump may be run conti'nuously without effecting any re-adjustment of position of the various elements of the road machine.

In the event it is desired to regulate the vertical position of the scoop bucket which is mounted on the frame work of the road scraping appara- This fluid will enter through these ports 15 into the housing of each of the tus, fluid must be suppliedto either one end or the other of the cylinder 25, which is connected by a pair of hoses 220 and HI to the ports 30 and 8|, respectively, of the manifold 10, which ports are in direct communication with the ports 16 and 11 of the valve 10. By way of illustration, it is assumed that it is desired to lower the frame Work toward the surface over which it is adapted to travel, and consequently it will be appreciated that fluid must be bled from the lower end of the cylinder through the conduit 22I and pumped into the upper end of the cylinder '25 through the conduit 220. In order to accomplish this result, the handle I53 is moved to the left, as viewed in Fig. 10, consequently causing a simultaneous upward movement of the plungers I I22 and I44. This upward movement of the plunger I22 is sufficient to raise this valve plunger I22 to a point where the lateral ports I6I are closed by the cylindrical bore I2l in the portion thereof between the annular ports I26 and I20. This inherently ent that the only escape for the fluid supplied by the pump will be through this path. A

As pressure is supplied by the pump. the pressure will be built up in the chamber I20 and this pressure, as will be clearly seen by reference to Fig. 16, will be exerted upon the lower surface ofuthe pistonlike member I35 formed in the central portion of the valve stem I34 of the poppet valves I32 and I33. The upward movement of the valve plunger I44 simultaneously with the upward'movement of the valve plunger I22 serves to raise theplunger I44 to a point where this plungerserves to establish communication between the chambers I36 and I31. As the pistonlib like member I35 is raised. communication will automatically be established between the chamber I28 and the chamber I36 and fluid will flow therethrough, and it will likewise be seen that upward movement of the pistonlike member I35 will serve to raise the poppet valves I32 and I33 from their seats and open the ports which these poppet valves serve to control. It will be clear that fluid may flow from the chamber I20 into the chamber I36 past reduced diameter portions of the valve plunger into the chamber I31 out through the ports controlled by the poppet valve I32, and consequently out, through the escape ports 16 of the valve housing 10. Inasmuch as this port 16 is directly in communication with the port 80 in the manifold 18. it ,will be seen that fluid supplied by the pump will be pumped under pressure through the port 80 into the hose or flexible conduit 220. which, as has been described ports 11. This fluid may flow into thevalve housing through the ports 11 and inasmuch as the poppet valve I33 is raised from its seat, the fluid may flow past this poppet valve into the chamber I39, out through a passageway 230, which, as has beendes'cribed, is in communication with an annular port I42 surrounding the bore I43, in which the plunger I44 operates. Inasmuch as the lower end of the valve plunger I44 is considerably smaller than the bore in which this valve plunger operates, it will be clear that the fluid may escape from the annular ports I42,"out through the lower end of the bore I43, and consequently will drain until the desired lowering of the framework of the scraper has been obtained, at which time it may be returned to the neutral position shown in therefrom into the reservoir I05 in the housing Fig. 10, and it will be clear that as soon as the valve is swung to this neutral position, fluid will be again permitted to escape through the lateral ports I 6| and consequently the pressure on the under side of thepistonlike'member. I 35 will be relieved and the poppetyalves I 32 and I33 will be returned to their seats, positively sealing the system and retaining the framework in predetermined adjusted position. i i

In the event that it is now desiredto raise the framework, the controlhandle I 53 is swung to the right, as isviewed in Fig. 10,'causinga downward movement of the 'valyerplung'eis I 22-and I44, such downward, movement being of about the same magnitude as the upward movement described above. It will be seen that this downward movement serves to move the plungerf-|22 to a position wherethe lateral ports I 6I thereof are sealed bythe wall of the bore I2I existing between the annular ports I20 and I21. This downward movement inherently serves to move the reduced diameter portion I23 of the. valve plunger I22 into a position where this reduced diameter portion bridges the ports I20 and I26, establishing communication .therebetween. Consequently fluid supplied through the inlet ports 15 of thevalve 10 will flow into the chamber I20 upwardly past the reduced diameter portion I23 of the valve plunger I22 into the chamber I26,

from whence it is" free to flow into the central.

chamber I28. This pressure exerted on the, lower side of the pistonlike member I servesto open,

the poppet valves I32 and I33.. Inasmuch as the valve plunger l22 has ,been moved downwardly,

, it will be apparent that the plunger I44 must inherently have been moved a like distance downwardly. Consequently, the enlarged diameter portion I46 thereof will serve to 'close the lower end of the bore I43, in which this plunger operates, and communication will be established between the annular ports I40, and I 42. It will be seen that when thevalve member is 'in this position, fluid will be free to flow from the chamberI28 past the pistonlike, member I35 into the chamber I36, annular port I40, pastthe reduced diameter portion of the valve I44, into the chamber I42, and through the passageway 230 to the poppet valve I33.

- Inasmuch as this poppet valve is retained in open position, this fluid will flow through the opening controlled .by this poppet valve and out through the ports 1, into the conduit 22I, which communicates with the lower end of the cylinder M 25. As this fluid under pressure is forced into the lower end of the cylinder 25, this will consequently cause an upward movement of the piston in thiscylinder .and consequently expel I fluid from the upper end of the cylinder back through the conduit 220 to the ports 16. Inasmuch as the poppet valve I32 is retained open by the pressure existing on the lower side of the pistonlike member. I35, it will be seen that this fluid is free to flow past the poppet valve I32 into the chamber I31, and annular port I surrounding the bore I'43. Inasmuch as the enlarged diameter portion N of the valve plunger I44, which serves to seal this port when the valve is in neutral position, has now been moved downwardly sufficiently far to open this port, it will be clear that the fluid thus returned may enter the bore I43 and spill over the top thereof, where it will normally drain into the reservoir I05 in the housing IIIII.

From the foregoing, it will be clear that the valve member 10 is easily and conveniently adjustable to any one of three positions,the central or neutral position being disclosed in the drawings, and that movement of the handle to either the left or right, as viewed in Fig. 10, serves to raise or lower the framework of the scraper, as

may be desired. It will further be apparent that due to the sealing effect obtained by the poppet valves I32 and I33, the elevation of the scraper mechanism may be accurately retained and regulated in any intermediate position which may be desired, and that due to this tight sealing effect obtained by these poppet valves, once the scraper framework has been adjusted to a predetermined position,'it can be retained almost into and the bleeding of fluid from the cylinders 40 which serve to actuate this scoop; is substantially identical with that described in connection with the valve member 10. The ports 16 and 11 of this valve member 1|, as hasbeen described above, are in direct communication with the ports 82 and 83 in the manifold 18 and these ports 82 and 83 are connected by means of their respective flexible conduits 23 6 and 231 to the permanent conduits 49 and .48, respectively,

which communicate with the respective rear and forward ends of the cylinders 40 which serve to control dumping actuation of the scoop 35.

Inasmuch as fluid is constantly supplied by means of the manifold 13 to all three of the ports 15 of the valve members 10, 1| and 12, it will be clear that fluid under pressure is constantly available at the ports 15 of the valve 1|. It will be clear by reference to Fig. 16 that as the actuating handle I99 of this valve is. moved either to-the right or to the left, the consequent movement of the primary plunger I18 of this valve serves to preclude communication between the port I12 I of this valve and the chamber I11 surrounding fdownward or upward movement of the plunger I18 will cause an actuation of the hydraulic cylinders 40 in substantially the same manner as thecylinder described in connection with the valve 10.

With the valves 10 and H in neutral position,

it ,will be seen that movement of the handle 2M of the valve 12 to either the right or left will similarly control the supply of fluid through flexible conduits -240 and I to the cylinders 53 serving to control actuation of the pivotally mounted gate 50.

From the foregoing it will be appreciated that the construction described herein provides a fluid distribution system in which fluid is supplied through a manifold to all of the valves in the bank. The construction and arrangement of the system is such that'with all of the valves in neutral position, the fluid must follow a tortuous path through all three of the valves in order to escape and that this path is continually maintained open as long as the valves are in neutral position and.

consequently no action of the hydraulic mechanism is obtained. It is also clearly apparent that any one of the valves in the bank may be operated independently of the others and that actuation of any of the individual valves serves to stop bleeding of the fluid through the system and 1 serves to direct the supply of fluid underpressure to the particular system which it is the desired to actuate,

It will be clearly appreciated that the specific embodiment of the invention illustrated in the accompanying drawings and described above is merely illustrative of the broad inventive concept presented in this application. Many other and further modifications of the system disclosed herein falling within the scope of the invention as defined in the subjoined claims wilLbe clearly apparent to those skilled in the art.

I claim as my invention:

1. In a fluid distribution system, a housing having a side wall structure, a plurality of valves interiorly of said housing and mounted adjacent said side wall structure, said valves being mounted in side-by-side spaced relation, each of said valveshaving an inlet port and a pair of feed ports adjacent said side wall .structure, a manifold common toall of said valves mounted exteriorly of said side wall structure, said side wall structure having apertures therein serving to es-. tablish communication between said'valve ports and said manifold, said manifold having a chamber in communication with all of the inlet ports of said valves and a port in communica ion with each of said outlet ports of said valves, and securing means extending through said side wall structure serving to lock said manifold and said valves in sealed relation with respect to said side wall structure and to each other whereby to mount said valves and manifold with respect to said housing.

2. In a fluid distribution system's; plurality of independently operable valves, each of said valves being a dual bore, fluid pressure piston valve comprising a housing having dual bores connected by a cross-over passage, a receiver piston valve in one of thebores constructed to receive and release fluid when in a normal position and to receive and direct the fluid to the cross-over passage when in another position to build up fluid pressure therein, a distributor piston valve in the other of the bores, means providing distributing passages in the housing, means for moving both of said valves in unison, said distributor piston valve being constructed to selectively direct fluid to the distributing passages, a spring loaded plunger valve element movably disposed within said cross-over passage and movable in response to said build-up of fluidpressure therein to allow fluid to flow to said other of the bores, and a tap- 75 I pet valve in at least one of said distributing passages and connected to said plunger for movement therewith to control flow of fluid to said one distributing passage, a manifold common to all of said valves mounted on and exteriorly of said housings, said manifold having a chamber in communication with one of the bores in each of the valves, the construction and arrangement of the receiver pistons being such that when all of said receiver pistons are in normal position fluid flows through said chamber, and when any one of said receiver pistons is in another position the flow of fluid through said chamber is blocked.

3. In a fluid distribution system a plurality of independently operable valves, each of said valves being a fluid pressure-piston valve comprising a housing havingparallel bores providing a receiver bore and a distributor bore connected by a cross-over passage, an inlet port communicating with said receiver bore, a receiver piston valve in said receiver bore constructed to receive and release fluid when in a normal position and to receive and direct the fluid to the cross-over passage when in another position to build up fluid pressure therein, a distributor piston valve in the distributor bore, means providing distributing passages in the housing, means for moving both of said valves in unison. said distributor piston valve being constructed to selectively direct fluid to the distributing passages, a spring loaded plunger valve element movably disposed within said cross-over passage and movable in response to said build-up of fluid pressuretherein to allow fluid to flow to said distributor bore, and a tappet valve in one of said distributing passages and connected to said plunger for movement therewith to control flow of fluid to said one distributing passage, a manifold common to all of said valves mounted on and exteriorly of said housing, said manifold having a chamber in communication with one of the bores in each of the valves, one of said receiver piston valves being hollow so that when it is in normal position fluid flows from the inlet port of the corresponding valve through said hollow receiver piston valve and into said chamber, the construction and arrangement of the other receiver piston valves being such that when such other receiver pistons are in normal position fluid flows from said chamber through the receiver bores of saidother receiver pistons in series, and when any one of said receiver piston valves is in another position the flow of fluid through said chamber is blocked.

EDWARD R. BARRETT. 

